A liquid cooling pipe connector convenient to disassemble
By adjusting the design of the buckle and the flow-stopping mechanism, the problems of thread damage and liquid leakage during frequent disassembly of liquid cooling pipe connectors are solved, enabling rapid disassembly and installation and improving equipment maintenance efficiency and lifespan.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- NINGBO HONGWU PIPE IND
- Filing Date
- 2026-03-20
- Publication Date
- 2026-06-16
AI Technical Summary
Existing liquid cooling pipe connectors are prone to thread stripping and bolt breakage when frequently disassembled, and liquid can easily leak out during disassembly, leading to equipment contamination and cleaning difficulties.
An easy-to-disassemble liquid cooling pipe connector was designed, which adopts an adjustable snap-fit mechanism and a flow-stopping mechanism. The snap-fit connection and liquid flow-stopping are achieved by sliding and rotating the adjustable component to prevent liquid from flowing out.
It enables quick disassembly and installation, avoids damage to threaded connections, reduces equipment contamination and cleaning costs, and extends equipment lifespan.
Smart Images

Figure CN121897801B_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of liquid cooling pipe connector technology, specifically a liquid cooling pipe connector that is easy to disassemble. Background Technology
[0002] Liquid cooling pipes are the core channels for transporting cooling media in liquid cooling systems. They are divided into two categories: rigid pipes and flexible pipes. Their core function is to efficiently transfer heat, helping the system to save energy, improve efficiency, and reduce costs. Liquid cooling pipes are the key channels for transporting cooling media (water, coolant, synthetic oil, etc.) in liquid cooling systems. They are mainly used to connect liquid cooling sources to equipment, between equipment, or between equipment and other pipelines. They are divided into rigid pipes (metal copper pipes, PVDF rigid pipes, etc.) and flexible pipes (PTFE, FEP, PFA, EPDM rubber hoses, etc.).
[0003] The main components of existing technology, such as Figure 19 As shown, it includes a liquid cooling pipe and mounting parts for connecting connectors at both ends of the liquid cooling pipe. One end of the mounting part is fixedly connected to the liquid cooling pipe, and the other end is fixedly connected to the connector by a thread. The connector consists of two parts, which are respectively connected to the liquid cooling pipe, other equipment, or other pipelines.
[0004] Most existing liquid cooling pipes and connectors use threaded connections. During installation, tools are needed to screw one end of the liquid cooling pipe into the connector. While this connection method can complete the connection to a certain extent, when the connector needs to be disassembled frequently, the threaded connection is prone to irreversible damage such as stripped threads and broken bolts as the number of disassemblies increases. Moreover, after long-term use, the threads may rust, making it difficult to disassemble and replace them later. In addition, when the existing connectors are disassembled, the liquid remaining inside the liquid cooling pipe may flow out with the removal of the connector, causing damage and contamination to the internal parts of the equipment, and requiring a lot of manpower and resources to clean up the leaked medium.
[0005] Therefore, the present invention provides a liquid cooling pipe connector that is easy to disassemble and does not easily cause residual liquid inside the liquid cooling pipe to flow out when the connector is disassembled. Summary of the Invention
[0006] To address the problem that existing connectors are difficult to disassemble, a new type of liquid cooling pipe connector that is easy to disassemble has been designed.
[0007] The technical solution adopted by the present invention to solve its technical problem is: a liquid cooling pipe connector that is easy to disassemble, including a pipe body and a connecting component for connecting the pipe body to other mechanisms, wherein a flow-cutting mechanism is fixedly connected to one end of the pipe body, and an adjusting buckle mechanism for installing the connecting component is connected to the end of the flow-cutting mechanism away from the pipe body.
[0008] The adjusting latching mechanism includes an installation component and several sets of latching components inside one end of the installation component. An adjusting component is slidably connected to the outside of the installation component. When installing the connecting component, the connecting component is moved into the installation component by sliding the adjusting component. Then, the adjusting component is reset to drive the latching components to latch and connect with the connecting component and limit the connection component.
[0009] The flow-blocking mechanism includes a first adjusting component and an adjusting part that is connected to the adjusting member at one end of the first adjusting component. The adjusting part includes several sets of flow-blocking members inside, which are used to adjust the liquid inside the pipe by rotating the adjusting member when the connecting component is disassembled, so as to avoid residual liquid inside the pipe from flowing out and causing pollution and requiring cleaning during disassembly.
[0010] Furthermore, the adjusting buckle mechanism also includes a sealing element inside the mounting component, and an elastic element for assisting the adjusting component to reset is provided between the adjusting component and the mounting component. The two ends of the elastic element are fixedly connected to the mounting component and the adjusting component, respectively. The mounting component is used to install the connecting assembly, and several sets of buckles are evenly distributed inside the mounting component. The buckles are slidably disposed inside the mounting component.
[0011] Furthermore, the mounting component includes a first protrusion internally provided for abutting the connecting assembly and improving the sealing effect. The end of the mounting component near the intercepting mechanism has a sealing groove for installing the sealing element. The end of the mounting component away from the intercepting mechanism has several sets of first adjustment grooves about the buckle. The opening size of the first adjustment groove near the inner wall of the mounting component is smaller than the diameter of the buckle to prevent the buckle from detaching from the mounting component. The outer side of the mounting component has a second adjustment groove for adjusting the rotation of the adjustment element. The outer side of the mounting component has a protrusion for limiting the elastic element. The end of the elastic element away from the adjustment element is fixedly connected to the limiting element.
[0012] Furthermore, the adjusting member includes a protruding stop at the end away from the intercepting mechanism, which is used to prevent the snap-fit member from disengaging from the first adjusting groove and to maintain the snap-fit connection stability of the connecting component. The end of the adjusting member close to the intercepting mechanism is provided with several sets of evenly distributed first teeth. The adjusting member is connected to the intercepting mechanism through the first teeth. The adjusting member is provided with a slider, which is used to rotate and adjust the adjusting member in conjunction with the second adjusting groove.
[0013] Furthermore, the flow-cutting mechanism also includes a fixing member with one end fixedly connected to the pipe body, and the end of the first adjusting component away from the adjusting part is fixedly connected to the end of the fixing member away from the pipe body. The adjusting part also includes a second adjusting component that is pulsatorically connected to the adjusting member. The upper and lower ends of several sets of flow-cutting members are slidably connected to the second adjusting component and the first adjusting component, respectively, for stably adjusting the middle size of several sets of flow-cutting members to cut off the flow in the pipe body.
[0014] Furthermore, the first adjustment component includes several sets of third adjustment grooves opened about the flow-stopping component at the end away from the fixing component, several sets of evenly distributed second teeth are opened on the outer side of the second adjustment component, a second protrusion is provided inside the end of the second adjustment component near the mounting component, and several sets of fourth adjustment grooves are opened inside the second adjustment component about the flow-stopping component.
[0015] Furthermore, the second adjustment component is connected to the adjustment member via the second tooth, and the second adjustment component is rotatably connected to the end of the mounting member near the throttling mechanism via the second protrusion.
[0016] Furthermore, the flow-blocking component includes a first sliding member fixedly connected at the upper end and a second sliding member fixedly connected at the lower end, with the first and second sliding members slidably connected to the fourth and third adjustment grooves, respectively.
[0017] Furthermore, the connecting assembly includes a first connector and a second connector that are respectively connected to the pipe body and other mechanisms. The first connector is connected to the pipe body through an adjusting snap-fit mechanism and a flow-stopping mechanism.
[0018] Furthermore, the first connector includes a connecting end for connecting to the second connector, and the outer side of the first connector for connecting to the adjusting buckle mechanism has a slot for buckling with the buckle and a contact surface for abutting against the first protruding end face inside the mounting component.
[0019] The beneficial effects of this invention are:
[0020] (1) The liquid cooling pipe connector that is easy to disassemble according to the present invention is made by sliding the adjusting component, inserting the first connector into the installation component, and then releasing the adjusting component so that it automatically resets under the action of the elastic component. At the same time, multiple sets of snap fasteners are driven to snap fasten to the slot of the first connector. The stop block of the adjusting component limits the snap fasteners. When disassembling, the adjusting component can be slid to release the snap fastener limit and the connector can be removed directly. The operation time is short, greatly improving the maintenance efficiency. At the same time, it avoids the problem of the existing threaded connection being unable to disassemble after multiple disassemblies due to thread stripping and rust.
[0021] (2) The liquid cooling pipe connector that is easy to disassemble according to the present invention can be disassembled by rotating the adjusting component, so that the first tooth meshes with the second tooth of the second adjusting component, thereby driving the second adjusting component to rotate, and then the multiple sets of intercepting components slide synchronously in the third adjusting groove and the fourth adjusting groove, quickly closing the liquid channel inside the pipe body, avoiding residual liquid from flowing out and contaminating the internal components of the equipment, causing short circuits or corrosion damage, and at the same time, saving the manpower and material costs of cleaning the leaked medium, indirectly extending the service life of the equipment. Attached Figure Description
[0022] The present invention will be further described below with reference to the accompanying drawings and embodiments.
[0023] Figure 1 This is a schematic diagram of the main structure of the present invention;
[0024] Figure 2 This is a schematic diagram of the first connector structure of the present invention;
[0025] Figure 3 This is a schematic diagram of the adjusting latch mechanism and the flow-stopping mechanism of the present invention;
[0026] Figure 4 This is a partial sectional view of the adjusting latch mechanism of the present invention;
[0027] Figure 5 This is a cross-sectional view of the adjusting buckle mechanism of the present invention;
[0028] Figure 6 This is a schematic diagram of the mounting component structure of the present invention;
[0029] Figure 7 This is a schematic diagram of the adjusting component structure of the present invention;
[0030] Figure 8 This is a schematic diagram of the structure of the adjusting buckle mechanism of the present invention when connected to the first connecting member;
[0031] Figure 9 For the present invention Figure 8 A partially enlarged sectional view at point A;
[0032] Figure 10 For the present invention Figure 8 A partially enlarged sectional view at point B;
[0033] Figure 11 For the present invention Figure 8 A partially enlarged sectional view at point C;
[0034] Figure 12 This is a schematic diagram of the flow interception mechanism of the present invention;
[0035] Figure 13 This is a top view of the interception mechanism structure of the present invention;
[0036] Figure 14 This is a cross-sectional view of the second adjustment component structure of the present invention;
[0037] Figure 15 This is a schematic diagram of the structure of the second adjustment component of the present invention;
[0038] Figure 16 This is a schematic diagram of the structure of the first adjustment component of the present invention;
[0039] Figure 17 This is a schematic diagram of the flow-blocking component structure of the present invention;
[0040] Figure 18 This is a schematic diagram of the flow-stopping mechanism of the present invention when it is closed;
[0041] Figure 19 This is a schematic diagram of the main structure of the prior art referenced in this invention.
[0042] In the diagram: 1. Pipe body; 2. Connecting assembly; 21. First connector; 211. Connecting end; 212. Slot; 213. Contact surface; 22. Second connector; 3. Adjusting buckle mechanism; 31. Mounting component; 311. First protrusion; 312. Sealing groove; 313. First adjusting groove; 314. Second adjusting groove; 315. Limiting component; 32. Sealing component; 33. Buckle component; 34. Adjusting component; 341. Stop block; 342. First tooth; 343. Slider; 35. Elastic component; 4. Flow interception mechanism; 41. Fixing component; 42. First adjusting assembly; 421. Third adjusting groove; 43. Second adjusting assembly; 431. Second tooth; 432. Second protrusion; 433. Fourth adjusting groove; 44. Flow interception component; 441. First sliding component; 442. Second sliding component. Detailed Implementation
[0043] To make the technical means, technical features, objectives and effects of this invention easier to understand, the invention will be further described below in conjunction with specific embodiments.
[0044] Example: Figure 1 - Figure 19 As shown, the present invention provides a liquid cooling pipe connector that is easy to disassemble, comprising a pipe body 1 and a connecting assembly 2 for connecting the pipe body 1 to other mechanisms. One end of the pipe body 1 is fixedly connected to a flow-stopping mechanism 4, and the end of the flow-stopping mechanism 4 away from the pipe body 1 is connected to an adjusting latching mechanism 3 for installing the connecting assembly 2. The adjusting latching mechanism 3 includes a mounting component 31 and a plurality of latching components 33 disposed inside one end of the mounting component 31. An adjusting component 34 is slidably connected to the outside of the mounting component 31, which is used to move the connecting assembly 2 into the mounting component 31 by sliding the adjusting component 34 when installing the connecting assembly 2, and then reset the adjusting component 34 to drive the latching components 33 to latch and limit the connection with the connecting assembly 2. The flow-stopping mechanism 4 includes a first adjusting component 42 and an adjusting part that is pulsatorically connected to the adjusting component 34 at one end. The adjusting part includes a plurality of flow-stopping components 44 disposed inside, which is used to rotate the adjusting component 34 when disassembling the connecting assembly 2 to drive the plurality of flow-stopping components 44 in the adjusting part to adjust and cut off the liquid inside the pipe body 1.
[0045] Specifically, pipe body 1 is a liquid cooling pipe, which is the core channel for transporting cooling medium in the liquid cooling system. It is mainly used for the transition connection between liquid cooling source and equipment, between equipment, or between equipment and other pipelines. The connection component 2 includes a first connector 21 and a second connector 22 that are respectively connected to pipe body 1 and other mechanisms. The first connector 21 is connected to pipe body 1 through adjusting buckle mechanism 3 and flow-stopping mechanism 4. The second connector 22 is used to connect other equipment or pipelines. Flow-stopping mechanism 4 is normally in the open state.
[0046] When connecting the first connector 21 and the pipe body 1, the first connector 21 can be inserted into the mounting part 31 by sliding the adjusting part 34. As the first connector 21 moves, the buckle 33 loses the obstruction of the adjusting part 34 and slides. When the first connector 21 comes into contact, it means that the installation is complete. At this time, the adjusting part 34 can be released. As the adjusting part 34 resets, it squeezes the buckle 33 to make it snap-fit with the first connector 21. At the same time, the adjusting part 34 limits the buckle 33, thereby ensuring the connection stability with the first connector 21. At the same time, when it is necessary to disassemble the first connector 21, the first connector 21 can be removed by sliding the adjusting part 34. No tools are needed and the disassembly and installation of the first connector 21 can be completed quickly. Even after multiple disassemblies, it can still maintain a good connection effect.
[0047] Meanwhile, when disassembling the connecting assembly 2 and the pipe body 1, the first connecting piece 21 is installed by sliding the adjusting member 34. Then, by rotating the adjusting member 34, the adjusting part is rotated, which in turn drives the several sets of intercepting members 44 set inside the adjusting part to intercept the flow in the pipe body 1. During subsequent installation, the flow interception in the pipe body 1 can be released by sliding the adjusting member 34 and rotating it in the opposite direction. This avoids the leakage of residual liquid inside the pipe body 1 when disassembling the connecting assembly 2, which would cause damage and pollution to the internal structure of the equipment. It also avoids the need to spend a lot of manpower and resources to clean up the leaked medium, thereby improving the service life of the equipment to a certain extent and saving a lot of manpower and resources.
[0048] In this embodiment, the adjusting buckle mechanism 3 further includes a sealing element 32 disposed inside the mounting member 31, and an elastic element 35 for assisting the adjusting member 34 to reset is disposed between the adjusting member 34 and the mounting member 31. The adjusting member 34 includes a stop block 341 protruding inside at the end away from the intercepting mechanism 4, and several sets of evenly distributed first teeth 342 disposed inside at the end of the adjusting member 34 near the intercepting mechanism 4. The adjusting member 34 is connected to the intercepting mechanism 4 through the first teeth 342. A slider 343 is disposed inside the adjusting member 34, and the adjusting member 34 is rotated and adjusted by the slider 343 in cooperation with the second adjusting groove 314.
[0049] The first connector 21 includes a connecting end 211 for connecting the second connector 22. The outer side of the first connector 21 for connecting the adjusting buckle mechanism 3 is provided with a buckle groove 212 for buckling with the buckle 33 and a contact surface 213 for abutting against the end face of the first protrusion 311 inside the mounting component 31.
[0050] Specifically, such as Figure 2 - Figure 7 As shown, the mounting part 31 is used to install the internal structures of the adjusting buckle mechanism 3 and to complete the buckle connection with the first connecting part 21. The sealing part 32 is used to seal the first connecting part 21 to prevent leakage of the liquid transported inside the pipe body 1. The buckle part 33 is set as a round ball, the elastic part 35 is set as a spring, the size of the slot 212 is adapted to the buckle part 33, and the outer side of the buckle part 33 is inserted into the slot 212 to complete the buckle connection with the first connecting part 21. The outer side of the adjusting part 34 is treated with friction to prevent slippage during adjustment, thereby improving the adjustment effect. The adjusting part 34 slides and compresses the elastic part 35, so that the buckle part 33 can slide and adjust to complete the disassembly and installation of the first connecting part 21. At the same time, when the adjusting part 34 rotates, it can act as a driving part, driving the flow-stopping mechanism 4 to rotate through the first tooth 342 set at one end.
[0051] The fastener 33 and the elastic element 35 can also be set to any other structure that can achieve the same effect. The two ends of the elastic element 35 are fixedly connected to the mounting part 31 and the adjusting part 34 respectively. The mounting part 31 is used to install the connecting component 2. Several sets of fasteners 33 are evenly distributed inside the mounting part 31. The fasteners 33 are slidably disposed inside the mounting part 31. The stop block 341 is used to prevent the fasteners 33 from disengaging from the first adjusting groove 313 and to maintain the stability of the fastening connection with the connecting component 2. As the adjusting part 34 slides, the stop block 341 releases the restriction on the fasteners 33.
[0052] In this embodiment, the mounting component 31 includes a first protrusion 311 internally provided for abutting the connecting component 2 and improving the sealing effect. The end of the mounting component 31 near the flow-blocking mechanism 4 has a sealing groove 312 for installing the sealing component 32. The end of the mounting component 31 away from the flow-blocking mechanism 4 has several sets of first adjustment grooves 313 about the buckle 33. The outer side of the mounting component 31 has a second adjustment groove 314 for adjusting the rotation of the adjusting component 34. The outer side of the mounting component 31 has a protruding limiting component 315 for limiting the elastic component 35. The end of the elastic component 35 away from the adjusting component 34 is fixedly connected to the limiting component 315.
[0053] Specifically, such as Figure 3 - Figure 5As shown, the first protrusion 311 is a trapezoidal protrusion with inclined surfaces on both sides. After the first connector 21 is installed inside the mounting component 31, the contact surface 213 on the outer side of one end of the first connector 21 abuts against one side of the first protrusion 311. This is used to further improve the sealing effect by contacting the sealing component 32 with the inclined surfaces. The opening size of the first adjusting groove 313 near the inner wall of the mounting component 31 is smaller than the diameter of the snap fastener 33, which is used to prevent the snap fastener 33 from detaching from the mounting component 31. The second adjusting groove 314 is U-shaped in general, including horizontal sections at both ends and a vertical section in the middle. The slider 343 inside the adjusting component 34 slides and rotates inside the second adjusting groove 314. The number of horizontal sections inside the second adjusting groove 314 can be increased, and the liquid flow cross section inside the pipe body 1 can be changed by rotating the adjusting component 34 at different angles, thereby achieving the effect of adjusting the flow rate.
[0054] In this embodiment, the flow-blocking mechanism 4 further includes a fixing member 41 with one end fixedly connected to the pipe body 1, and the end of the first adjusting component 42 away from the adjusting part is fixedly connected to the end of the fixing member 41 away from the pipe body 1. The adjusting part further includes a second adjusting component 43 that is pulsatorically connected to the adjusting member 34. The upper and lower ends of a plurality of flow-blocking members 44 are slidably connected to the second adjusting component 43 and the first adjusting component 42 respectively, for stably adjusting the middle size of the plurality of flow-blocking members 44 to block the flow in the pipe body 1.
[0055] Specifically, such as Figure 8 - Figure 18 As shown, the fixing member 41 is used to install the internal structure of the flow-blocking mechanism 4 and the connecting pipe 1. The first adjusting component 42 is in a fixed state, and the second adjusting component 43 can rotate with the adjusting member 34. When the second adjusting component 43 rotates, it can drive the flow-blocking member 44 to slide on the first adjusting component 42, thereby changing the space in the middle of several sets of flow-blocking members 44. The rotation amplitude of the adjusting member 34 inside the second adjusting groove 314 is consistent with the rotation amplitude required for the flow-blocking mechanism 4 to complete opening and closing. Figure 13 The flow interception mechanism 4 is in the open state. Figure 18 The flow interception mechanism 4 is in the closed state;
[0056] When the flow-stopping mechanism 4 is in the open state, the size of the middle part of several sets of flow-stopping parts 44 is slightly smaller than the size of the internal flow channel of the connecting component 2. The upper and lower ends of the several sets of flow-stopping parts 44 are in close contact with the end faces of the first adjusting component 42 and the second adjusting component 43, respectively. The liquid flowing inside the pipe body 1 will not enter the interior of the second adjusting component 43 from the flow-stopping parts 44. One end of the second connecting part 22 installed inside the mounting part 31 is disconnected from the end face of the second adjusting component 43. A seal is provided between the second adjusting component 43 and the mounting part 31. Therefore, the liquid flowing inside the pipe body 1 will not leak through the flow-stopping mechanism 4. The closed structure inside the flow-stopping mechanism 4 is sufficient to prevent the liquid inside the liquid cooling pipe from flowing out. Because it is in the closed state during maintenance, the liquid inside the liquid cooling pipe loses its driving force, so the closed structure is sufficient to prevent the liquid from flowing out, or the time that the closed structure blocks the liquid is sufficient to complete the maintenance of the liquid cooling pipe.
[0057] In this embodiment, the first adjusting component 42 includes several sets of third adjusting grooves 421 opened about the flow-blocking component 44 at the end away from the fixing component 41, several sets of evenly distributed second teeth 431 opened on the outer side of the second adjusting component 43, a second protrusion 432 is provided inside the end of the second adjusting component 43 near the mounting component 31, and several sets of fourth adjusting grooves 433 are opened inside the second adjusting component 43 about the flow-blocking component 44. The flow-blocking component 44 includes a first sliding component 441 fixedly connected at the upper end and a second sliding component 442 fixedly connected at the lower end. The first sliding component 441 and the second sliding component 442 are slidably connected to the fourth adjusting groove 433 and the third adjusting groove 421, respectively.
[0058] Specifically, such as Figure 15 - Figure 17 As shown, the second adjusting component 43 is connected to the adjusting member 34 via the second tooth 431. The second adjusting component 43 is rotatably connected to the end of the mounting member 31 near the intercepting mechanism 4 via the second protrusion 432. At the same time, the second protrusion 432 is rotatably installed inside the mounting member 31 to fix the second adjusting component 43. The first tooth 342 at one end of the adjusting member 34 corresponds to and meshes with the second tooth 431 on the outside of the second adjusting component 43. When the adjusting member 34 slides, the first tooth 342 can slide inside the second tooth 431. When the second adjusting component 43 rotates, it drives the intercepting member 44 to slide through the fourth adjusting groove 433 in conjunction with the first sliding member 441. At the same time, as the intercepting member 44 slides, its bottom end slides on the first adjusting component 42 via the second sliding member 442. The third adjusting groove 421 is a horizontal groove; the fourth adjusting groove 433 is an arc-shaped groove.
[0059] Working principle: First, the adjustment buckle mechanism 3 and the flow interception mechanism 4 are installed. Then, the first connector 21 and the pipe body 1 are connected. The first connector 21 can be inserted into the installation part 31 by sliding the adjustment part 34. As the first connector 21 moves, the buckle 33 loses the obstruction of the adjustment part 34 and slides. When the contact surface 213 of one end of the first connector 21 comes into contact with the first protrusion 311, the installation is complete. At this time, the adjustment part 34 can be released. As the adjustment part 34 is reset by the elastic part 35, it squeezes the buckle 33 to make it snap-fit with the first connector 21. At the same time, the adjustment part 34 limits the buckle 33, thereby ensuring the connection stability with the first connector 21. At the same time, when it is necessary to disassemble the first connector 21, the first connector 21 can be removed by sliding the adjustment part 34. No tools are needed and the disassembly and installation of the first connector 21 can be completed quickly. Even after multiple disassemblies, it can still maintain a good connection effect.
[0060] Meanwhile, when disassembling the connecting assembly 2 from the pipe body 1, the first connecting member 21 is installed by sliding the adjusting member 34. Then, by rotating the adjusting member 34, the second adjusting assembly 43 is rotated, which in turn moves several sets of flow-blocking members 44 inside the second adjusting assembly 43, gradually reducing the space in the middle to block the flow in the pipe body 1. During subsequent installation, the flow blocking in the pipe body 1 can be released by sliding the adjusting member 34 and rotating it in the opposite direction. This prevents the liquid remaining inside the pipe body 1 from flowing out when disassembling the connecting assembly 2, which could damage or contaminate the internal structure of the equipment. It also avoids the need to spend a lot of manpower and resources to clean up the leaked medium, thereby improving the service life of the equipment to a certain extent and saving a lot of manpower and resources.
[0061] The foregoing has shown and described the basic principles, main features, and advantages of the present invention. Those skilled in the art should understand that the present invention is not limited to the above embodiments. The embodiments and descriptions in the specification are merely illustrative of the principles of the invention. Various changes and modifications can be made to the invention without departing from its spirit and scope, and all such changes and modifications fall within the scope of protection claimed by the present invention. The scope of protection of the present invention is defined by the appended claims and their equivalents.
Claims
1. A liquid cooling pipe connector that is easy to disassemble, comprising a pipe body and a connecting assembly for connecting the pipe body to other mechanisms, characterized in that: One end of the pipe is fixedly connected to a flow-cutting mechanism, and the end of the flow-cutting mechanism away from the pipe is connected to an adjusting buckle mechanism for installing the connecting components. The adjusting buckle mechanism includes an installation component and several sets of buckle components disposed inside one end of the installation component. An adjusting component is slidably connected to the outside of the installation component. When installing the connecting component, the connecting component is moved into the installation component by sliding the adjusting component. Then, the adjusting component is reset to drive the buckle components to buckle and limit the connection with the connecting component. The flow-blocking mechanism includes a first adjusting component and an adjusting part that is connected to the adjusting member at one end of the first adjusting component. The adjusting part includes several sets of flow-blocking members inside, which are used to rotate the adjusting member to drive the several sets of flow-blocking members inside the adjusting part to adjust and block the liquid inside the pipe when the connecting component is disassembled. The adjusting component has several sets of evenly distributed first teeth inside the end near the intercepting mechanism, and the adjusting component is connected to the intercepting mechanism through the first teeth. The adjustment section also includes a second adjustment component that is connected to the adjustment member in a transmission manner. The upper and lower ends of several sets of flow-blocking members are slidably connected to the second adjustment component and the first adjustment component, respectively, for stably adjusting the middle size of the several sets of flow-blocking members to cut off the flow in the pipe body. The second adjustment component has several sets of evenly distributed second teeth on its outer side, and the second adjustment component is connected to the adjustment member through the second teeth.
2. The easily detachable liquid cooling pipe connector according to claim 1, characterized in that: The adjusting buckle mechanism also includes a sealing element inside the mounting component, and an elastic element for assisting the adjusting component to reset is provided between the adjusting component and the mounting component. The two ends of the elastic element are fixedly connected to the mounting component and the adjusting component, respectively. The mounting component is used to install the connecting component. Several sets of buckles are evenly distributed inside the mounting component, and the buckles are slidably disposed inside the mounting component.
3. The easily detachable liquid cooling pipe connector according to claim 2, characterized in that: The mounting component includes a first protrusion inside for abutting the connecting assembly and improving the sealing effect. The end of the mounting component near the flow-blocking mechanism has a sealing groove for installing the sealing element. The end of the mounting component away from the flow-blocking mechanism has several sets of first adjustment grooves about the buckle. The outer side of the mounting component has a second adjustment groove for adjusting the rotation of the adjustment element. The outer side of the mounting component has a protruding limiting element for limiting the elastic element. The end of the elastic element away from the adjustment element is fixedly connected to the limiting element.
4. The easily detachable liquid cooling pipe connector according to claim 3, characterized in that: The adjusting component includes a stop block with a protrusion at one end away from the intercepting mechanism, which is used to prevent the buckle from disengaging from the first adjusting groove. The adjusting component is provided with a slider inside, and the adjusting component is rotated and adjusted by the slider in conjunction with the second adjusting groove.
5. The easily detachable liquid cooling pipe connector according to claim 4, characterized in that: The flow interception mechanism also includes a fixing member that is fixedly connected to the pipe body at one end, and the end of the first adjustment component away from the adjustment part is fixedly connected to the end of the fixing member away from the pipe body.
6. The easily detachable liquid cooling pipe connector according to claim 5, characterized in that: The first adjustment component includes several sets of third adjustment slots at the end away from the fixing member, the second adjustment component has a second protrusion inside the end near the mounting member, and several sets of fourth adjustment slots are opened inside the second adjustment component.
7. The easily detachable liquid cooling pipe connector according to claim 6, characterized in that: The second adjustment component is rotatably connected to the end of the mounting piece near the throttling mechanism via a second protrusion.
8. The easily detachable liquid cooling pipe connector according to claim 1, characterized in that: The flow-blocking component includes a first sliding member fixedly connected at the upper end and a second sliding member fixedly connected at the lower end. The first sliding member and the second sliding member are slidably connected inside the fourth adjustment groove and the third adjustment groove, respectively.
9. The easily detachable liquid cooling pipe connector according to claim 3, characterized in that: The connection assembly includes a first connector and a second connector that are respectively connected to the pipe body and other mechanisms. The first connector is connected to the pipe body through an adjusting snap-fit mechanism and a flow-stopping mechanism.
10. The easily detachable liquid cooling pipe connector according to claim 9, characterized in that: The first connector includes a connecting end for connecting to the second connector. The outer side of the first connector for connecting to the adjusting buckle mechanism has a slot for buckling with the buckle and a contact surface for abutting against the first protruding end face inside the mounting component.